Modelling of Nitric Oxides and Carbon Monoxide Emissions from Bagasse-Fires Boilers. The project aims to develop computational models to predict emissions of nitric oxides and carbon monoxide from sugar-mill boilers burning bagasse. Bagasse combustion does not contribute to greenhouse gas emissions and clean and efficient combustion of this fuel has become very important for the sugar industry and for Australia. The project combines the opportunity of direct boiler measurements by SRI with the m ....Modelling of Nitric Oxides and Carbon Monoxide Emissions from Bagasse-Fires Boilers. The project aims to develop computational models to predict emissions of nitric oxides and carbon monoxide from sugar-mill boilers burning bagasse. Bagasse combustion does not contribute to greenhouse gas emissions and clean and efficient combustion of this fuel has become very important for the sugar industry and for Australia. The project combines the opportunity of direct boiler measurements by SRI with the modelling expertise at the University to develop combustion-kinetics models for these species. The models will be incorporated into the previously developed computational fluid dynamics - combustion code of the furnace to give the capability of emission prediction as a function of burner operating conditions and fuel parameters.Read moreRead less
Special Research Initiatives - Grant ID: SR0354551
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
ARC Research Network for Renewable Energy. The proposed Research Network will integrate and coordinate the entire research field of renewable energy in Australia. This Network covers a diverse range of technologies, and includes all prominent researchers in the area of renewable energy in Australia. The Network is strengthened by the inclusion of key people from government agencies, industry, industry associations and international research organisations.
Australia is a leading player in the ....ARC Research Network for Renewable Energy. The proposed Research Network will integrate and coordinate the entire research field of renewable energy in Australia. This Network covers a diverse range of technologies, and includes all prominent researchers in the area of renewable energy in Australia. The Network is strengthened by the inclusion of key people from government agencies, industry, industry associations and international research organisations.
Australia is a leading player in the world's renewable energy industry. An effective structure for networking and for the exchange of people, information and research results will maintain and improve Australia's position in this rapidly growing industry.Read moreRead less
Thermal isolation: a novel pathway to transforming complex waste. This project aims to establish a novel pathway for transforming complex waste otherwise destined for landfill into valuable products and resources. By leveraging high temperature reactions, the team plans to thermally isolate useful carbons and silica from within automotive shredder residue (ASR) in situ, to produce activated carbon products and silica layers, and so completely recycle this bulk toxic waste for the first time. Suc ....Thermal isolation: a novel pathway to transforming complex waste. This project aims to establish a novel pathway for transforming complex waste otherwise destined for landfill into valuable products and resources. By leveraging high temperature reactions, the team plans to thermally isolate useful carbons and silica from within automotive shredder residue (ASR) in situ, to produce activated carbon products and silica layers, and so completely recycle this bulk toxic waste for the first time. Such innovative new pathways for separating out valuable materials from complex and toxic wastes offer industries an alternative low-cost and sustainable source of raw materials, while reducing pressures on landfills and finite natural resources.Read moreRead less
Sustainable Technology for Removal of Trace Contaminants in Rural Water Supplies. Provision of safe drinking water treatment using sustainable technology which can be applied in rural locations and emergency situations is the main aim of this project. A hybrid membrane process will be combined with solar energy for the removal of pathogens and trace pollutants such as uranium, fluoride, arsenic, boron and nitrates. The technology will be designed for remote community situations and hence be robu ....Sustainable Technology for Removal of Trace Contaminants in Rural Water Supplies. Provision of safe drinking water treatment using sustainable technology which can be applied in rural locations and emergency situations is the main aim of this project. A hybrid membrane process will be combined with solar energy for the removal of pathogens and trace pollutants such as uranium, fluoride, arsenic, boron and nitrates. The technology will be designed for remote community situations and hence be robust and low in maintenance. Using solar energy is a challenge for trace contaminant removal as the operating conditions vary with the power fluctuations, which presents a substantially different situation to grid power connection.Read moreRead less
Sequestration of CO2 with enhanced methane recovery from deep coal. Coal and gas represent the main energy source for the Australian and many other national economies into the foreseeable future. The continuing use of these critical resources requires that greenhouse gas emission issues be addressed. Any serious attempt to achieve reduced emission of CO2 from power generation requires sequestration as a necessary element. A plausible method for cost effective sequestration of large amounts of ....Sequestration of CO2 with enhanced methane recovery from deep coal. Coal and gas represent the main energy source for the Australian and many other national economies into the foreseeable future. The continuing use of these critical resources requires that greenhouse gas emission issues be addressed. Any serious attempt to achieve reduced emission of CO2 from power generation requires sequestration as a necessary element. A plausible method for cost effective sequestration of large amounts of CO2 is by geological fixing in deep, unminable coal. The key technological and scientific issues regarding capacity, rate, technical viability and site selection form the basis of this proposal.Read moreRead less
Cost effective in-line filtration system to improve water quality in rainwater tanks. This research will provide the basis for developing an affordable and innovative water treatment solution for domestic rainwater collection systems. The main elements of this research are:
. Provision of a cost -effective submerged membrane operated under gravity to provide water of potable standard.
. Establishing an adaptive membrane cleaning system using the concept of volume control.
. Characterisati ....Cost effective in-line filtration system to improve water quality in rainwater tanks. This research will provide the basis for developing an affordable and innovative water treatment solution for domestic rainwater collection systems. The main elements of this research are:
. Provision of a cost -effective submerged membrane operated under gravity to provide water of potable standard.
. Establishing an adaptive membrane cleaning system using the concept of volume control.
. Characterisation protocol of membrane fouling and stored rain water.
. Sizing of a permeate tank for storing treated water through demand management.
This project will increase the use of rainwater tanks, helping available water resources to go further.Read moreRead less
Cost effective treatment system for stormwater harvesting for medium scale developments. Stormwater harvesting is central to the integrated water cycle management approach now being formally endorsed by all tiers of governments as the best way to manage our water resources. Despite its immense potential, stormwater harvesting in urban centres throughout Australia is largely limited to household rainwater tanks. By developing economical and efficient treatment systems suitable for medium density ....Cost effective treatment system for stormwater harvesting for medium scale developments. Stormwater harvesting is central to the integrated water cycle management approach now being formally endorsed by all tiers of governments as the best way to manage our water resources. Despite its immense potential, stormwater harvesting in urban centres throughout Australia is largely limited to household rainwater tanks. By developing economical and efficient treatment systems suitable for medium density developments, this project will maximise the resource value of stormwater, and reduce demand on water supply systems. The project will lead to the development of medium sized communities within larger urban centres that maximises its use of stormwater for water needs.Read moreRead less
Removal of Potential Impact of Pharmaceutical Active Compounds during Wastewater Treatment. The increasing application of antimicrobial compounds in pharmaceutical and personal care products (PPCPs) requires improved understanding of their impact on the environment. Wastewater treatment plants (WWTPs) are a major removal process, however little is known about why certain PPCPs are removed during wastewater treatment and other are not. The project aims to study the fate of PPCPs and the spread of ....Removal of Potential Impact of Pharmaceutical Active Compounds during Wastewater Treatment. The increasing application of antimicrobial compounds in pharmaceutical and personal care products (PPCPs) requires improved understanding of their impact on the environment. Wastewater treatment plants (WWTPs) are a major removal process, however little is known about why certain PPCPs are removed during wastewater treatment and other are not. The project aims to study the fate of PPCPs and the spread of bacterial resistance in wastewater treatment. Studies will compare the effects of different treatment processes, operational conditions and environmental factors on the removal and treatment of PPCPs. The outcome will be the development of more sustainable WWTPs design and operation in terms of PPCPs removal.Read moreRead less
Optimal management of corrosion and odour problems in sewer systems. Pollutants in wastewater undergo complex changes in sewers, leading to the production and release of odorous and corrosive compounds. Despite major efforts and expenditure by water utilities to mitigate these problems, odorous emissions from sewers are still commonly occurring in urban areas. Furthermore, the value of public assets is significantly diminished due to sewer corrosion, costing hundreds of millions of dollars a yea ....Optimal management of corrosion and odour problems in sewer systems. Pollutants in wastewater undergo complex changes in sewers, leading to the production and release of odorous and corrosive compounds. Despite major efforts and expenditure by water utilities to mitigate these problems, odorous emissions from sewers are still commonly occurring in urban areas. Furthermore, the value of public assets is significantly diminished due to sewer corrosion, costing hundreds of millions of dollars a year in Australia alone. This project is a major joint effort by the Australian water industry and world-leading scientists to generate advanced knowledge and develop effective technologies for optimal odour and corrosion management in sewers, delivering large social, environmental and economic benefits.Read moreRead less
Understanding the Biotransformation Processes in a Sewer System to Achieve Optimal Management. Sewer corrosion and odour emissions are incurring massive costs to the wastewater management authorities. These problems are primarily caused by the hydrogen sulfide produced by the in-sewer biotransformation processes. Through integrating controlled laboratory experiments, extensive field measurement/experiments and advanced computer modelling, the project aims to generate a fundamental understanding ....Understanding the Biotransformation Processes in a Sewer System to Achieve Optimal Management. Sewer corrosion and odour emissions are incurring massive costs to the wastewater management authorities. These problems are primarily caused by the hydrogen sulfide produced by the in-sewer biotransformation processes. Through integrating controlled laboratory experiments, extensive field measurement/experiments and advanced computer modelling, the project aims to generate a fundamental understanding of the in-sewer biotransformation processes, in particular those occurring in sewer biofilms and sediments, and to provide scientific and engineering support to the wastewater authorities to manage their sewers in a more cost-effective way. Emphasis is placed on the integrated sewer and wastewater treatment performance to achieve overall optimal wastewater management.Read moreRead less